Tool for cutting machining

ABSTRACT

A tool for cutting machining comprises a tool body, a cutting member and a fastener for fastening the cutting member to the tool body. The tool body has a shank, a central bore formed therethrough, and a front surface having grooves formed therein. The cutting member includes a cemented carbide body having a cutting edge formed in a front surface thereof, and a rear supporting surface. The supporting surface includes ridges received in the grooves, and a rearwardly open blind hole. The fastener extends through the central bore and is threadedly connected to the blind threadedly connected to the blind bore for pulling the cutting member against the tool body.

TECHNICAL BACKGROUND

The present invention relates to a tool for rotary, cutting machining,including a tool body, a cutting portion and means for fastening. Thetool body has a front surface and the cutting portion has a supportsurface provided to dismountably abut against each other, substantiallyin a radial plane. The invention also relates to a separate tool tip, acutting portion, a tool body as well as to a method for manufacturing atool tip or a cutting portion.

It is previously known to use interchangeable cutting edges on differenttypes of tools for cutting machining. This technique has however itspractical limitation because of strength reasons when it comes tomilling- and drilling tools rotating around its longitudinal axis.

Through U.S. Pat. No. 4,684,298 is previously known a drill with adismountable cutting portion secured in a drill body by two screws,which are provided opposite sides of a central line of the drill. In theknown drill, screws transfer torsion which is created during drilling,to the drill body. Such a drill suffers from a number of drawbacks,partly that it becomes statically unstable, which is solved bypositioning resilient sleeves around the screws, and partly that thecutting portion is forced to contain less amount of cemented carbide(since the screws need space) whereby the propensity for crack formationincreases. In addition the screws are submitted to shear forces andexchange of the cutting portion becomes troublesome.

Furthermore, it is previously known through European Document 0 358 901to provide a drill with a dismountable cutting portion secured in adrill body by means of at least one screw, which is eccentricallypositioned relative to the rotational axis of the drill. The cuttingportion carries two indexable cutting inserts, and a pilot drill extendscentrally therethrough. This known drill has the same drawbacks asmentioned above.

OBJECTS OF THE INVENTION

The present invention has as one object to provide milling or drillingtools with interchangeable cutting edges, which eliminates the problemsof prior art tools.

Another object of the present invention is to provide a rigid tool,preferably for drilling or milling, where the cutting portion wedginglycooperates with the tool body such that the clamping force increaseswith increasing feed force.

Another object of the present invention is to provide a tool, preferablyfor drilling or milling, where the cutting portion is firmly held by acentral fastening means.

Another object of the present invention is to provide a rigid tool,preferably for drilling or milling, where the cutting portion easily canbe exchanged.

Another object of the present invention is to provide a tool and acutting portion where the advantage with grooves is combined with theproduction of injection molded cemented carbide.

Still another object of the present invention is to provide a tool and acutting portion in which the cutting portion can not be positionedobliquely even if one of the cooperating grooved surfaces is worn.

Still another object of the present invention is to provide a tool and acutting portion where axial or tangential cutting forces are distributedon a large surface such that the risk for breaking the cutting portion,is reduced.

Still another object of the present invention is to provide a tool and acutting portion where the relative movement between the cutting portionand the tool body is negligible even after wear of the tool body.

Still another method object of the present invention is to provide amethod for manufacturing a cutting portion or tool tip whereby thedegree of freedom for geometrical appearance is substantially unlimited.

These and other objects have been achieved by a tool comprised of a toolbody, a cutting member, and a fastener for securing the cutting memberto the tool body. The tool body defines a longitudinal axis and includesa shank terminating in a front surface. The cutting member is formed ofcemented carbide and has a cutting edge on a forwardly facing surfacethereof. A rearwardly facing support surface of the cutting memberincludes a screw-threaded blind hole. The support surface and frontsurface include mutually engaging grooves and ridges. The fastenerextends through the tool body and is screw threaded in the blind holefor pulling the cutting member toward the tool body.

The invention also relates to the cutting member per se, and to the toolbody per se.

DESCRIPTION OF THE DRAWINGS

FIG. 1 shows a drilling tool according to the present invention, in apartly sectioned, perspective view;

FIG. 2 shows a cutting portion according to the present invention in aperspective view;

FIG. 3 shows the cutting portion in a side view;

FIG. 4 shows the cutting portion in a top view;

FIG. 5 shows the cutting portion in a bottom view;

FIGS. 6 and 7 show cross sections according to lines A--A and B--B inFIG. 4;

FIG. 8 shows the drill tip according to FIG. 1 in magnification;

FIGS. 9, 10 and, 11 show enlarged cross sections of cooperating supportsurfaces in FIG. 8; and

FIGS. 12 and 13 show an alternative embodiment of a tool according tothe invention.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS OF THE INVENTION

The embodiment of a tool according to the invention shown in FIG. 1 is aso called helix drill, which comprises a tool tip or a cutting portion10, a pull rod 11, a drill body 12 and a retainer nut 13.

The cutting portion 10 is provided with at least one cutting edge 19 atthe end facing away from the drill body 12, which edge is given aconfiguration depending on the area of application. Alternatively, thecutting edge would be (or the cutting edges would be) substantiallystraight and parallel to the longitudinal center axis of the cuttingportion if the tool were an end mill, while the cutting edges would becircular if the tool were a ball nose end mill. The forward end of thedepicted cutting portion 10 shows an edge 19 for drilling. Theappearance and the area of application of the tool may vary in severalways.

The cutting portion 10 is made of hard material, preferably cementedcarbide and most preferably of injection molded cemented carbide andcomprises two upper clearance surfaces 15, a support surface 16, a pairof curved first surfaces 17 and a pair of curved second surfaces 18. Thesurfaces 17, 18 connect the support surface 16 with the clearancesurfaces 15. All these surfaces and resulting edges are made of the samematerial, i.e., preferably of injection molded cemented carbide. Linesof intersection between the second curved surfaces or the chip flutes 18and the clearance surfaces 15 form the main cutting edges 19, preferablyvia reinforcing chamfers, not shown. Lines of intersection between thefirst curved the surfaces 17 and the chip flutes 18 form secondarycutting edges 20. The chip flute can alternatively be adapted for adrill body with straight chip flutes. The cutting portion preferablyalso comprises a coring-out surface 21, which reaches the center of thecutting portion and which forms an angle δ, FIG. 6, with the rotationalaxis 22 of the tool. The angle δ lies within the interval of 40 to 50°,preferably 45°. The biggest diameter of the cutting portion is thediametrical distance D between the radial extreme points of thesecondary cutting edges 20. The height Y of the cutting portion issubstantially the same as the distance D, in order to minimize the wearfrom chips on the joint between the cutting portion and the drill body.The biggest diameter d of the support surface 16 is preferably less thandiameter D, in order to obtain clearance at machining. Flushing holes23, 23A, being substantially parallel with the rotational axis 22,extend through the cutting portion from the support surface 16 to theorifice in respective upper clearance surfaces 15. The flushing holesare provided on a common line 1 on each side of the axis 22.

The support surface 16 is provided with a number of separate,substantially identical and parallel grooves or ridges 30. The ridgesform a substantially sinusoidal curve in the cross section according toFIG. 8, which curve travels about a line which substantially lies in theplane of surfaces 29A, 29B, described below with reference to FIG. 10.The ridges are elongated. The ridge 30 further has two flanks 32A, 32B,which extend to the ridge bottom 31. The bottom can be described by aradius of about 0.2 to 0.4 mm. The flanks form an acute angle ε witheach other. The angle ε lies within the interval of 40° to 80°,preferably between 55° and 60°. A crest or a curved surface 33A, 33B isprovided on each side of the ridge 30. Each surface 33A, 33B touchinglyconnects to the associated flank via a soft transition, and joins withthe other surface 33A, 33B at the tip of the ridge. Each ridge may besubstantially parallel with the line 1 or form an acute angle with theline 1. Each ridge forms an angle φ with a line K, intersecting theradial extreme points of the chip flutes 18 on the side of the cuttingedge in the support surface 16. The angle φ is about 0° to 90°,preferably 30° to 60°. The ridge has a height h and a largest width w.The number of ridges 30 depends indirectly on the diameter D of thecutting portion and the number of ridges varies between 2 to 20 and forexample can be mentioned that about 9 ridges is provided on a drill ofthe diameter 18 mm.

The cutting portion is provided with the support surface 16 at the endfacing the drill body 12, which surface 16 is provided with a firstmeans for engagement 14, which in the shown embodiment comprises athreaded recess and a truncated, conical guiding surface 35.

An end of the pull rod 11 facing towards the cutting portion, isprovided with an additional, externally threaded part 36, which isfollowed axially rearwards by a conical widening 37, which are intendedto cooperate with the first means for engagement 14. In an operativesituation the threaded recess 34 cooperates with the other threaded part36.

In the other end of the pull rod 11 is provided a further externalthreaded part, which cooperates with a cylindrical nut 13 provided witha key grip 38. The nut is inserted in a boring 39 in the shank portion40 of the drill body, wherein the nut and the shank portion includecooperating, radial contact surfaces at 41. The contact surface 41 givesaxial support for the nut after tightening. The boring connectsconcentrically to a central, smaller channel 25 in the drill body, saidchannel extending forwards to and terminating centrally in the frontsurface 24 of the drill body. The drill body is provided with flushchannels 23A, which follow protruding lands of the drill, along ahelical path on substantially constant distance from the rotational axis22. The drill body has screw shaped chip flutes 18A or straight chipflutes and these may extend through the body or through of a partthereof.

The drill body 12 is provided with a front surface 24 at the end facingtowards the cutting portion 10, which surface is provided to abutagainst the support surface of the cutting portion 10. The largestdiameter of the front surface is smaller than the largest diameter D ofthe cutting portion but preferably the same as the smallest diameter dof the cutting portion.

The front surface is provided with a number of separate, identicalrecesses or grooves 26, which in cross section describe a substantiallytrapezoidal path. The grooves are elongated and extend along essentiallythe entire front surface. Each groove may be substantially parallel withthe line 1 or form an acute angle with the line 1. Each groove forms theangle φ with the line K, which intersects the radial extreme points ofthe chip flutes on the cutting edge side in the front surface 24. Theangle 0 is about 0° to 90° and preferably 30° to 60°. Each groove 26 hastwo flanks 28A, 28B, which connect to the bottom 27, via a sharp orrounded transition. The flanks form an acute angle α with each other.The angle α lies within the interval of 40° to 80°, preferably 55° to60°. A planar surface 29A, 29B is provided on each side of the groove26. Each surface is preferably planar and connects to the associatedflank via an obtuse inner, soft or sharp, transition. The number ofgrooves 26, which depends of how the support surface of the cuttingportion is formed, is consequently the same as the number of ridgeswhich the support surface has, the number being in the interval of 2 to20 grooves. The groove has a depth d, and a largest width z. The bottomcan alternatively be described by a radius of about 0.2 to 0.4 mm.

The height of the ridge is 50% to 95% of the groove 26 depth and thelargest width w of the ridge is bigger than the biggest width z of thegroove. This results in a gap p between the crest 33A and the bottom 27when mounting the cutting insert in the holder. The gap ensures that theflanks engage with each other and that the bottom does not support thecutting insert, and therefore tilting is avoided. A corresponding gaparises also above the planar surfaces 29A, 29B. The ridges and thegrooves form, in mounted condition, a joint with a number of wedginglyeffective connections which entail an increase in the frictional forcewith increasing feed force. Another advantage with said wedging effectis that it allows a certain oblique positioning of the ridges and thegroove relative to each other in connection with the initial stage ofmounting, wherein these are guided correctly by its geometry duringcontinuing compression. The joint is placed such that it usually will besituated in the drill hole during the drilling. The ridges and thegrooves should be placed on respective surfaces such that the resultwill be as many long ridges and grooves as possible. The ends of a ridgeor a groove should be as far from each other as possible for best momenttransfer.

Mounting of the cutting portion 10 on the drill body 12 takes place asfollows. The pull rod is brought into in the boring 39 and through thecentral hole 25 of the drill body 12 until nut 13, which is connected tothe axially rear end of the pull rod, abuts against the contact surface41. The forward part 36 of the pull rod and the conical widening 37thereby project centrally from the front surface 24. Then the threadedpart 36 is brought into in the recess 14 and the cutting portion isrotated and is threaded onto the pull rod until the surfaces 35 and 37abut against each other. Then the support surface 16 of the cuttingportion is brought by hand into contact with the front surface. Atrotation of the nut 13 via a key which is in engagement with the keygrip 38, the cutting portion 10 is drawn firmly against the frontsurface, i.e. the position according to FIG. 1 has been achieved. Thecutting portion 10 is now anchored in a satisfactorily manner in thedrill body 12. The pull rod is in this position substantially intendedto retain the cutting portion during extraction of the tool from themachined hole, i.e. the pull rod transfers the feed forces substantiallyalone, while the ridges and the grooves receive the forces and momentumwhich are created by the cutting machining. However, the force from thepull rod is large enough on the joint between the cutting portion andthe body to avoid loose fit at extraction. The ridges and the groovesintersect the chip flutes 18, 18A in a essentially common radial segmentor radial plane and the chip flutes extend axially on both sides if saidradial segment.

In this connection shall be pointed out that the threaded connectionbetween the cutting portion and the pull rod serves two purposes, namelyto place the cutting portion 10 in a fixed position in the drill body atmounting, and to ensure that the cutting portion 10 during use of thecutting tool, is always retrained in its fixed position.

By the cooperating ridges and grooves an interaction of the forces ateach contact surface or line of contact can be derived, wherecooperation of the flanks takes place, according to

    T'=P/n sin (α/2)/μ-cos (α/2)!

where T' is the shear force acting on one flank 28A or 28B of n numberof grooves, μ is the coefficient of friction and P is the resultantforce which arises from the feed. From the formula one can see that asmaller flank angle gives a higher shear force T' which counteracts"cogging over" caused by the drilling moment. A drill according to thepresent invention becomes statically stable and contains much cementedcarbide as well as unloading the pull rod both radially and axially.

By spreading the cutting forces on a larger surface the risk forsplitting the support surface 16 of the cutting portion is diminished.After the mounting, the ridges 30 and the grooves 26 will have contactsurfaces, which intersect the radial plane R, FIG. 11, a number oftimes, preferably at least four times, at locations radially outside theend 36 of the pull rod. The contact surfaces of the ridges and of thegrooves lie substantially in the radial plane R, i.e. they oscillateabout the radial plane R with an amplitude which is at maximum half theheight h of the profile. The height of the profile is maximum 20% of thecutting portion height Y. The total contact surface becomes 5 to 10%larger than conventional planar contact surfaces. The cutting portion 10can thus be removed from the front surface 24 when the pull rod 11 end36 is unscrewed, i.e. is moved from a first axially forward position toa second axially rearward position.

Then, the cutting portion 10 can be removed from the drill body 12 andbe exchanged.

In FIGS. 12 and 13 there is shown an alternative embodiment of a toolaccording to the invention, which comprises a tool tip or a cuttingportion 10', a pull rod 11', a drill body 12', an adjustment screw 50',a spring 51' and a retainer stop screw 52'. With this tool it ispossible to unload and exchange the cutting portion while the drill bodyis fixed in the machine.

The cutting portion 10' and the drill body 12' are substantiallyidentical to the ones described above. However the drill body has anobliquely inwardly and rearwardly directed, threaded boring 53', in thetransition between the securing end and the chip flutes, and an axiallyrearwards thread 54' in the boring 39'.

The axially forward end of the pull rod 11' comprises a concentricallywidened guiding surface 55' and parts 36' and 37' corresponding to theearlier described parts 36, 37. The axially rearward end of the pull rodhas a conical widening 56', which passes rearwardly into a cylindricalguiding surface 57', wherein the diameter of said guiding surface issomewhat less than the diameter of the boring 39'.

The drilling tool is mounted by bringing the pull rod into the boring39' and through the central hole of the drill body 12'. Then the spring51' is inserted into the boring 39', whereafter the external threadedstop screw 52' is screwed into the thread 54', and thereby the spring iscompressed and forces the pull rod ahead to a stop. The pull rod therebyassumes an axially forward position, and the threads in the cuttingportion and on the pull rod can cooperate. Also, the cutting portion canbe screwed firmly onto the pull rod, whereafter the adjustment screw 50'via the thread 53' can press against the widening 56' and push the pullrod rearwardly. Exchange of the cutting portion takes place as follows.The adjustment screw 50' is first unloaded on the side of the drillshank, and the pull rod 11' is pushed ahead, about 2 mm, due to thestored elastic energy in the spring 51'. The spent cutting portion isunscrewed, preferably by hand, and a new cutting portion is threadedfirmly on the pull rod until the conical part of the recess abutsagainst the forward conical part of the pull rod. Then one can continuein two different ways. Either the cutting portion is brought against thefront surface of the drill body by hand, such that the ridges and thegrooves come into engagement with each other, whereafter the adjustmentscrew 50' is tightened and the cutting portion is thereby fixed inoperative position. The other way is to let the screw 50' itself pushthe pull rod and the cutting portion rearwardly such that the ridges andthe grooves come into engagement with each other, such that the cuttingportion is fixed in operative position. The conical surface 56' can abutagainst a corresponding surface in the forward end of the boring 39'when the screw 50' is unscrewed. Thereby the friction between theconical surfaces counteracts rotation of the pull rod during unscrewingof the cutting portion. If friction is too low the screw 50' can bescrewed towards the cylindrical surface 56' and thus further lock thepull rod against rotation.

In both of the above described embodiments the cutting portion has awedging cooperation with the tool body, such that the clamping force orthe frictional force, i.e. the resistance against radial displacement ofthe portion relative to the body, increases with increasing feed force.In addition, the means for fastening are provided to influence thecutting portion in the same direction as the feed force during drillingi.e., the pull rod draws the cutting portion axially rearwardlysubstantially in the same direction in which the feed force acts.

It is understood that the geometries of the cooperating ridges andgrooves can be varied within the spirit of the present invention withoutdeparting from the scope of the claims. Consequently the geometries canassume most thread cross sections (however with a degree of overlap ofmax 95%), trapezoidal on both cooperating the surfaces, for example. Theinvention could be used also for milling cutters. The cutting portion ispreferably coated with layers of for example Al₂ O₃, TiN and/or TiCN. Incertain cases it can be advantageous with brazed on super hard materialssuch as CBN or PCD on the cutting edges.

Likewise, it is possible to utilize other clamping means than a centralpull rod; for example it is possible to maintain the cutting portion bya wedge, movable perpendicularly to the rotational axis.

Furthermore shall be pointed out that the above described embodimentsrelate to tools which rotate relative to its longitudinal axis or to thecenter axis of the workplace and that the means for retention rotateswith the tool. The tools can be used also as stationary tools incombination with a rotary work piece.

An aspect of the invention relates to a tool tip, which in its entiretyconsists of hard material such as injection molded cemented carbide,wherein it is possible to apply the invention to turning, milling,drilling or broaching inserts for metal machining or on cutting orpercussive inserts for rock drilling or mineral milling. At utilizationof the invention for metal machining, the tool tip or the cutting insertcomprises a central blind hole for receiving a fastening device, whereinthe recess has a thread 34 integral with the cutting insert. By that isintended that cutting inserts can be clamped from the lower side thereofby for example a screw, such that a large upper surface becomes amenablefor cutting edges or chip formers, which earlier were not possible touse. The thread is then chosen such that it does not become loose duringmachining.

The tool tip or the cutting portion is made as follows. Cemented carbideand a bearer, plastics for example, is mixed and is shaped to pellets orgranulate whereafter the mixture is inserted in a molding machine afterpreheating to a suitable temperature for the mixture, whereafter themixture under high pressure and high temperature, about 180° C., isinjected into an accurately shaped mould arranged with a certainconfiguration, corresponding to the design of the cutting portion or ofthe tool tip. The mould therefore contains parts in order to directly orindirectly create prerequisites for at least one cutting edge, at leastone clearance surface and a non-planar support surface and one or morecores for threads and flush channels, with the intention to convey thedesign to the cutting portion or the tool tip, whereafter the injectionmolded cemented carbide portion or tip may solidify in the mould and issubsequently is plucked out. The tip or portion is then sintered andpossibly machining can be performed, such as grinding of the clearancesurfaces. With the aid of this method the geometry of the portion or ofthe tip can be chosen regardless of the limitations of the conventionalmethod for injection molding. For example, chip breakers can be shapedon surfaces which until now only been able to be ground.

The invention is in no way limited to the above described embodimentsbut can be varied freely within the scope of the appended claims.

We claim:
 1. A tool for rotary cutting machining, comprising:a tool bodydefining a longitudinal axis and including a shank terminating in afront surface; a cutting member formed of cemented carbide, said cuttingmember having a cutting edge on a forwardly facing surface thereof, andincluding a rearwardly facing support surface engaging said frontsurface of said tool body, said support surface including a rearwardlyopen blind hole; said support surface and said front surface includingmutually engaging projections and recesses, said projections comprisingparallel and linear ridges, and said recesses comprising parallel andlinear grooves receiving respective ones of said ridges; a fastenerdisposed partly in said tool body and partly in said blind hole andexerting an axially rearward force on said cutting member for pressingsaid support surface of said cutting member against said front surfaceof said tool body, said fastener extending axially in said tool body,and said blind hole being axially aligned with said fastener; and flushchannels formed in said tool body and in said cutting member and alignedwith one another, said flush channels extending through said ridges andsaid grooves of conducting flushing fluid through said tool body and tosaid cutting edge.
 2. The tool according to claim 1 wherein said blindhole includes female screw threads, and said fastener includes malescrew threads coupled to said female screw threads.
 3. The toolaccording to claim 1 wherein the grooves include bottoms, and the ridgesinclude crests, said crests spaced axially from said bottoms to form agap therebetween.
 4. The tool according to claim 1 wherein said toolbody includes a bore extending along said axis, said fastener disposedwithin said bore and having a screw-threaded front end projectingforwardly past said front surface of said tool body, said blind holebeing screw threaded to said fastener, and a retainer for retaining thefastener in the tool body.
 5. A tool for rotary cutting machining,comprising:a tool body defining a longitudinal axis and including ashank terminating in a front surface; a cutting member formed ofcemented carbide, said cutting member having a cutting edge on aforwardly facing surface thereof, and including a rearwardly facingsupport surface engaging said front surface of said tool body, saidsupport surface including a rearwardly open blind hole; said supportsurface and said front surface including mutually engaging projectionsand recesses, said projections comprising parallel linear ridges, andsaid recesses comprising parallel linear grooves receiving respectiveones of said ridges, said grooves including bottoms, and the ridgesincluding crests, said crests spaced axially from said bottoms to form agap therebetween, said ridges defining a substantially sinusoidal curve,and said grooves defining a substantially trapezoidal curve, an axialheight of each ridge being 50 to 95 percent of an axial depth d of saidgroove; and a fastener disposed in said tool body and said blind holefor pressing said tool body and said cutting member toward one another.6. The tool according to claim 5 wherein a number of said grooves equalsa number of said ridges, said number being from 2 to 20.